Motor

ABSTRACT

A motor including: a rotor including a permanent magnet type rotor unit having a plurality of permanent magnets and a reluctance type rotor unit having a plurality of salient pole portions, the rotor units being coupled to each other in an axial direction; and a stator for generating a field for driving the rotor. The permanent magnet type rotor unit and the reluctance type rotor unit are given an angle deviation therebetween in the direction of rotation to obtain desired torque characteristics. The reluctance type rotor unit has slits for preventing flux leakage from the permanent magnets. The slits are formed with the angle deviation in the direction of rotation from respective positions symmetric about a center of the salient pole portions. Flux leakage is thus prevented to avoid deterioration in characteristics.

The present disclosure relates to subject matter contained in priorityJapanese Patent Application Nos. 2001-128113 and 2002-51069, filed onApr. 25, 2001 and Feb. 27, 2002 respectively, the contents of which isherein expressly incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a motor, and more particularly to amotor having a rotor which combines a permanent magnet type rotor unitand a reluctance type rotor unit for the sake of enhanced flexibility indesign.

2. Description of Related Art

Conventionally, there have been motors in which a permanent magnet typerotor unit having a plurality of permanent magnets and a reluctance typerotor unit having a plurality of salient pole portions are coupled toeach other in the axial direction for the sake of enhanced flexibilityin design. The known examples include ones disclosed in Japanese PatentLaid-Open Publications Nos. Hei. 7-59310 and Hei. 9-294362.

Japanese Patent Laid-Open Publication No. Hei. 7-59310 discloses thatthe permanent magnets and the salient pole portions are given an angledeviation therebetween in the direction of rotation to obtain desiredcharacteristics, and that a nonmagnetic material is interposed into thestator and between opposed portions of the permanent magnet type rotorunit and the reluctance type rotor unit of the rotor so that fluxleakage from the permanent magnets to the reluctance type rotor unit isprevented to avoid coupling in terms of magnetic circuits.

In Japanese Patent Laid-Open Publication No. Hei. 9-294362, however, thepermanent magnet type rotor unit and the reluctance type unit are simplycombined with each other. This causes a problem of inevitabledeterioration in characteristics due to interactions. More specifically,the problem is that the magnetic flux from the permanent magnets of thepermanent magnet type rotor unit can leak out to the reluctance typerotor unit, ending up with deterioration in characteristics. Moreover,since a current phase value at which the permanent magnet type rotorunit generates a maximum torque is different from one at which thereluctance type rotor unit generates a maximum torque, there is theproblem that the combined torque does not reach the sum of the maximumvalues.

Meanwhile, in Japanese Patent Laid-Open Publication No. Hei. 7-59310,the interposition of the nonmagnetic material between the permanentmagnet type rotor unit and the reluctance type rotor unit prevents theflux leakage, whereas there are problems of greater size and highercost.

Among possible technical means for solving these problems is onedisclosed in Japanese Patent Laid-Open Publication No. Hei. 11-196544 inwhich the reluctance type rotor unit is provided with slits forinterrupting magnetic flux from the permanent magnets. Now, an exampleof such configuration will be described with reference to FIGS. 16A-16C.The reference numeral 1 represents a motor, which includes a rotor 2 anda stator 3. The rotor 2 includes a permanent magnet type rotor unit 4having 2 n (n is a natural number) permanent magnets 5 and a reluctancetype rotor unit 6 having a plurality of salient pole portions 7. Therotor units 4 and 6 are coupled to each other in the axial direction.The reluctance type rotor unit 6 has slits 8 for preventing flux leakagefrom the ends of the permanent magnets 5. The slits 8 are formedsymmetrically about the center of the salient pole portions 7 so as torun within projected sections of the permanent magnets 5. The stator 3is provided with 3 n teeth 9. Each of the teeth 9 is-given a winding 10so as to generate a magnetic field for driving the rotor 2.

Practical experiments showed, however, that even in such configuration,i.e., when the slits 8 were formed to fall within the projected sectionsof the permanent magnets 5, flux leakage through outside the ends of theslits 8 was considerably greater than expectations. That is, the fluxleakage from the ends of the permanent magnets 5 to the reluctance typerotor unit 6 could not be prevented satisfactorily.

Besides, if the permanent magnet type rotor unit 4 and the reluctancetype rotor unit 6 are coupled to each other in the axial direction withan angle deviation in the direction of rotation so that the combinedcharacteristics of the torques generated by the permanent magnet typerotor unit 4 and the reluctance type rotor unit 6 become desirable,there may occur the problem that the effect of the slits 8 isinsufficient.

SUMMARY OF THE INVENTION

In light of the foregoing conventional problems, an object of thepresent invention is to provide a motor in which different types ofrotor units are coupled to obtain desired torque characteristics andallow the prevention of deterioration in characteristic as well withoutcausing an increase in size and a rise in cost.

A motor according to the present invention includes: a rotor including apermanent magnet type rotor unit having a plurality of permanent magnetsand a reluctance type rotor unit having a plurality of salient poleportions, the rotor units being coupled to each other in an axialdirection; and a stator for generating a field for driving the rotor.Here, the reluctance type rotor unit has slits for preventing fluxleakage from the permanent magnets. The slits run within projectedsections of the permanent magnets along respective circumferentialdirections thereof, and are extended beyond the projected sections ofthe permanent magnets at both ends. Since the slits are extended beyondthe projected sections of the permanent magnets at both ends, fluxleakage from the ends of the permanent magnets to the reluctance typerotor unit is prevented with reliability, thereby avoiding deteriorationin characteristics resulting from flux leakage.

The permanent magnet type rotor unit and the reluctance type rotor unitmay be given an angle deviation δ therebetween in the direction ofrotation, the angle deviation δ corresponding to a mechanical angleequivalent to a difference θ between a current phase value θ1 at whichthe permanent magnet type rotor unit generates a maximum torque and acurrent phase value θ2 at which the reluctance type rotor unit generatesa maximum torque (θ=θ1-θ2). The reluctance type rotor unit has slits forpreventing flux leakage from the permanent magnets, the slits beingformed with the angle deviation δ in a direction of rotation fromrespective positions symmetric about a center of the salient poleportions. Since the two types of rotor units are coupled to each otherwith as much a mechanical angle in the direction of rotation as thedifference between the current phase values for generating therespective maximum torques, the maximum output toque is achieved fortorque improvement. The slits formed with the angle deviation preventflux leakage from the permanent magnets as well. Besides, the absence ofa nonmagnetic material between the rotor units allows compactconfiguration and cost reduction.

The rotor may include a first reluctance type rotor unit adjoining tothe permanent magnet type rotor unit and a second reluctance type rotorunit adjoining to the first reluctance type rotor unit alone. In thiscase, the first reluctance type rotor unit has slits for preventing fluxleakage from the permanent magnets and has no angle deviation from thepermanent magnet type rotor unit in the direction of rotation. The firstreluctance type rotor unit and the second reluctance type rotor unit aregiven an angle deviation therebetween in the direction of rotation. Theabsence of an angle deviation between the permanent magnet type rotorunit and the first reluctance type rotor unit surely prevent fluxleakage from the permanent magnets at between the rotor units and avoiddeterioration in characteristics. Besides, the absence of a nonmagneticmaterial allows compact configuration and cost reduction withoutnecessitating a drop in torque for the sake of flux leakage prevention.In addition, the provision of an arbitrary angle deviation between thefirst and second reluctance type rotor units makes it possible to obtainarbitrary desired torque characteristics such as higher torque and lowervibration.

Another motor according to the invention includes: a rotor including apermanent magnet type rotor unit having a plurality of permanent magnetsand a reluctance type rotor unit having a plurality of salient poleportions, the rotor units being coupled to each other in an axialdirection; and a stator for generating a field for driving the rotor.Here, a gap dimension between the reluctance type rotor unit and thestator is made smaller than a gap dimension between the permanent magnettype rotor unit and the stator. The permanent magnet type rotor unitwhich undergoes higher centrifugal distortion due to the provision ofthe permanent magnets is given the greater gap dimension. Consequently,the permanent magnet type rotor unit and the reluctance type rotor unitare made equal in the limit of rotation speed, thereby allowing higherrotation speed. Since the gap dimension of the permanent magnet typerotor unit has a small influence on torque characteristics and the gapdimension of the reluctance type rotor unit has a great influence on thesame, the reluctance type rotor unit exerts a significant effect ofimproving the torque characteristics. The reluctance type rotor unitthus improves in efficiency.

Another motor according to the invention includes: a rotor including apermanent magnet type rotor unit having a plurality of permanent magnetsand a reluctance type rotor unit having a plurality of salient poleportions, the rotor units being coupled to each other in an axialdirection; a stator for generating a field for driving the rotor; andone or more bearings for supporting the rotor rotatably. Here, a bearingof great supporting strength out of them is arranged on a side of thepermanent magnet type rotor unit. Because of the rational bearingarrangement that the rotor is supported by the bearing of greatersupporting strength on the side of the permanent magnet type rotor unitwhich is high in mass, the rotor is stably supported with compactconfiguration.

Another motor according to the invention includes: a rotor including apermanent magnet type rotor unit having a plurality of permanent magnetsand a reluctance type rotor unit having a plurality of salient poleportions, the rotor units being coupled to each other in an axialdirection; and a stator for generating a field for driving the rotor.Here, the permanent magnet type rotor unit is arranged throughout anaxial width of the stator. The reluctance type rotor unit is arrangedoutside the axial width of the stator. Thereby, the q- and d-axisinductances are changed at the end of the permanent magnet type rotorunit. Consequently, the limit of rotation speed due to the generation ofinduced voltages in the permanent magnet type rotor unit is eliminatedto improve the motor in rotation speed characteristics. The design rangeof rotation speeds is thus expanded for higher maximum rotation speed.

Another motor according to the invention includes: a rotor including apermanent magnet type rotor unit having a plurality of permanent magnetsand a reluctance type rotor unit having a plurality of salient poleportions, the rotor units being coupled to each other in an axialdirection; and a stator for generating a field for driving the rotor.Here, a plurality of keyways for fixing a rotating shaft to thepermanent magnet type rotor unit and the reluctance type rotor unit arearranged so as to make a relative position between the permanent magnettype rotor unit and the reluctance type rotor unit selectable in thedirection of rotation, the rotating shaft connecting the rotor toexterior. Torque characteristic requirements are satisfied by selectingthe keyways accordingly. Thereby, the motor is used common to a varietyof torque characteristic requirements, which allows a reduction in cost.

Another motor according to the invention includes: a rotor including apermanent magnet type rotor unit having a plurality of permanent magnetsand a reluctance type rotor unit having a plurality of salient poleportions, the rotor units being coupled to each other in an axialdirection; and a stator for generating a field for driving the rotor.Here, the reluctance type rotor unit has notches for forming the salientpole portions in its periphery. The notches are connected at theperiphery by a connecting frame including a magnetic saturation parthaving such a width that magnetic saturation occurs with slight magneticflux. The periphery of the reluctance type rotor unit is thus madecircular with the connecting frame, whereby a medium stirring resistanceis eliminated for smooth effective rotation. Besides, there occursneither bypassing of magnetic flux through the connecting frame nor adrop in efficiency. Even if the permanent magnets at the end of thepermanent magnet type rotor unit get chipped, the chips are retainedinside the connecting frame and kept from flowing out, therebyprecluding adverse effects.

Hybrid type electric vehicles including the foregoing motors is reducedin the amount of magnets at a given identical output as compared tothose of magnet types. When the motors are driven reversely, theproduction of induced voltages is suppressed for lower iron loss. Thisincreases mileage per charge and prevents deterioration and breakage ofthe power supply batteries and the like.

Fuel-cell electric vehicles including the foregoing motors also offerthe same effects.

While novel features of the invention are set forth in the preceding,the invention, both as to organization and content, can be furtherunderstood and appreciated, along with other objects and featuresthereof, from the following detailed description and examples when takenin conjunction with the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a longitudinal sectional view showing the configuration of amotor according to a first embodiment of the present invention, FIG. 1Bis a sectional view taken along the arrowed line IB—IB of FIG. 1A, andFIG. 1C is a sectional view taken along the allowed line IC—IC of FIG.1A;

FIGS. 2A and 2B are torque characteristic charts of a conventionalexample and the present embodiment, respectively, showing motor torquecharacteristics;

FIG. 3 is a schematic diagram showing a reluctance type rotor unitaccording to a second embodiment of the invention;

FIG. 4 is a schematic diagram showing a modified example of thereluctance type rotor unit according to the embodiment;

FIG. 5 is a schematic diagram showing another modified example of thereluctance type rotor unit according to the embodiment;

FIG. 6 is a keyway layout according to a third embodiment of theinvention;

FIG. 7 is a keyway layout of a modified example of the embodiment;

FIGS. 8A to 8H are explanatory diagrams showing various key shapes inthe embodiment;

FIG. 9 is a schematic diagram showing a motor according to a fourthembodiment of the invention;

FIG. 10 is a schematic diagram showing a motor according to a fifthembodiment of the invention;

FIG. 11 is a schematic diagram showing a motor according to a sixthembodiment of the invention;

FIG. 12 is a schematic diagram showing a motor according to a seventhembodiment of the invention;

FIG. 13 is a schematic diagram showing a motor according to an eighthembodiment of the invention;

FIG. 14 is a schematic diagram showing a motor according to a ninthembodiment of the invention;

FIG. 15 is a schematic diagram showing a motor according to a tenthembodiment of the invention; and

FIG. 16A is a longitudinal sectional view showing a configurationexample of a conventional motor, FIG. 16B is a sectional view takenalong the arrowed line XVIB—XVIB of FIG. 16A, and FIG. 16C is asectional view taken along the allowed line XVIC—XVIC of FIG. 16A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, a first embodiment of the present invention will bedescribed with reference to FIGS. 1A to 2B.

FIG. 1A shows a rotor 2 of a motor 1. The rotor 2 includes a permanentmagnet type rotor unit 4 shown in FIG. 1B and a reluctance type rotorunit 6 shown in FIG. 1C. The permanent magnet type rotor unit 4 has four(2 n; n=2) arc-sectioned permanent magnets 5 such as rare-earth magnetsand ferrite magnets, which are embedded in a rotor core 11 with theircenters of curvature outward. The permanent magnets 5 are arranged so asto alternate between the N and S poles along the circumferentialdirection. The reluctance type rotor unit 6 includes a rotor core 12having four (2 n; n=2) salient pole portions 7 and notches 13therebetween.

The rotor 2 is constituted by coupling the permanent magnet type rotorunit 4 and the reluctance type rotor unit 6 to each other so that thepermanent magnets 5 and the salient pole portions 7 form electric anglesof 90° therebetween with a predetermined angle deviation δ in thedirection of rotation. The reluctance type rotor unit 6 has slits 8 forpreventing flux leakage from the permanent magnets 5. The slits 8 areformed with the angle deviation δ in the direction of rotation fromrespective positions symmetric about the center of the salient poleportions 7. The slits 8 are formed into arcs that pass through thecenters of the projected sections of the permanent magnets 5 across theaxial direction, and have the angle deviation δ from the salient poleportions 7. consequently, while the permanent magnet type rotor unit 4and the reluctance type rotor unit 6 are coupled with the angledeviation δ therebetween, the slits 8 run along the center lines of theprojected sections of the respective permanent magnets 5. The slits 8are extended beyond the projected sections of the permanent magnets 5 atboth ends, so as to prevent flux leakage from the permanent magnets 5.The width of the slits 8 is set at no less than twice the gap dimensionbetween the rotor 2 and a stator 3.

According to the foregoing configuration, the angle deviation in thedirection of rotation provided between the permanent magnet type rotorunit 4 and the reluctance type rotor unit 6 yields desired torquecharacteristics. For example, FIG. 2A shows the case where the permanentmagnets 5 and the salient pole portions 7 have electric angles of 90°therebetween. Here, the output torque, given by the sum of thechain-lined torque obtained from the permanent magnet type rotor unit 4(the sum of a magnet torque and part of a reluctance torque) and thebroken-lined torque obtained from the reluctance type rotor unit 6, hasa maximum value of T₀. FIG. 2B is for situations where the permanentmagnet type rotor unit 4 and the reluctance type rotor unit 6 form anangle of 90° plus an angle deviation δ of 15° in electric angle. In thiscase, the peak value of the torque from the permanent magnet type rotorunit 4 and the peak value of the torque from the reluctance type rotorunit 6 are added to achieve a maximum output torque T₁ (T₁>T₀). Inaddition, the rotor units 4 and 6 of different torque waveforms areadjusted in the angle deviation in the direction of rotation so thattorque ripples decrease for lower vibration.

Since the slits 8 are extended beyond the projected sections of thepermanent magnets 5 at both ends, flux leakage from the ends of thepermanent magnets 5 to the reluctance type rotor unit 6 is prevented,thereby avoiding deterioration in characteristics resulting from fluxleakage. In addition, since the slits 8 are formed with an angledeviation δ as described above, the slits 8 prevent flux leakage fromthe permanent magnets 5 with reliability, thereby avoiding deteriorationin characteristics resulting from flux leakage. Unlike the conventionalexample, a nonmagnetic material is not interposed between the rotorunits 4 and 6. This allows compact configuration and cost reduction.

Note that the angle deviation of the slits 8 need not always be set sothat the slits 8 run along the centers of the projected sections of thepermanent magnets 5. It may be set so that the silts 8 run within theprojected sections of the respective permanent magnets 5 when anarbitrary angle deviation is established between the permanent magnettype rotor unit 4 and the reluctance type rotor unit 6.

A nonmagnetic material is preferably arranged in the slits 8. Thisensures the prevention of flux leakage and suppresses a drop in strengthascribable to the slits 8.

Now, a second embodiment of the present invention will be described withreference to FIGS. 3 to 5. Characteristic parts of the embodiments to bedescribed below may be either combined with the configuration ofpreceding embodiments or used by themselves.

In the present embodiment, as shown in FIG. 3, the reluctance type rotorunit 6 has notches 13 for forming salient pole portions 7 in itsperiphery. The notches 13 are connected at the periphery by connectingframes 14. Along the entire length, the connecting frames 14 are made ofmagnetic saturation portions 15 having such a width that magneticsaturation occurs with slight magnetic flux. Incidentally, the magneticsaturation portions 15 may be arranged only in part.

According to the configuration described above, the periphery of thereluctance type rotor unit 6 is made circular by the connecting frames14. In such cases that the motor 1 is placed in a medium, a mediumstirring resistance is thus reduced for smooth rotation. Besides, thereoccurs neither bypassing of magnetic flux through the connecting frames14 nor a drop in efficiency.

Consequently, when the motor is applied to one for driving a compressoror the like to be placed in a medium such as a refrigerant, the rotationof the rotor 2 causes no medium stirring. Hence, a drop in efficiencyresulting from stirring resistance is suppressed and adverse effects onthe medium are precluded. Even if the permanent magnets 5 get chipped atends, the chips are retained inside the connecting frames 14 and keptfrom flowing out, thereby eliminating adverse effects.

Otherwise, as shown in FIG. 4, the connecting frames 14 may be eachprovided with magnetic saturation portions 15 at least on both ends anda wide part 16 in the middle. Aside from the foregoing effect, themidsections of the connecting frames 14 can thus secure strength andrigidity by means of the wide parts 16, thereby improving the strengthof the rotor 2. It is also possible to improve the durability of thecore mold, with a reduction in production cost.

Furthermore, as shown in FIG. 5, the connecting frames 14 may beprovided with fastening parts 17 of greater width, having bolt holes 18for axial fastening/fixing. These fastening parts 17 are fastened andfixed by bolts 19 for a further improvement in the strength of the rotor2.

Next, a third embodiment of the present invention will be described withreference to FIGS. 6 to 8H.

In the present embodiment, as shown in FIG. 6, the permanent magnet typerotor unit 4 and the reluctance type rotor unit 6 have a shaft hole 20into which a rotating shaft (not shown) for connecting the rotor 2 toexterior is fitted. In order to fix the rotating shaft to the permanentmagnet type rotor unit 4 and the reluctance type rotor unit 6, aplurality of keyways 21 are formed in either one or both of the shaftholes 20 in the permanent magnet type rotor unit 4 and the reluctancetype rotor unit 6. The plurality of keyways 21 are formed at angledeviations δ of 0°, δ₁, δ₂, and δ₃ (δ₁<δ₂<δ₃) with respect to referencelines drawn at intervals of 180° in electric angle (in the presentembodiment, at intervals of 90°), respectively. This makes the relativeposition (angle deviation) between the permanent magnet type rotor unit4 and the reluctance type rotor unit 6 selectable in the direction ofrotation. Alternatively, as shown in FIG. 7, keyways 22 of relativelysmall width may be formed around the shaft hole(s) 20 at angledeviations δ of 0°, δ₁, δ₂, δ₃, δ₄, δ₅, δ₆, and δ₇(δ₁<δ₂<δ₃<δ₄<δ₅<δ₆<δ₇) with respect to the reference lines. In thiscase, the range of adjustments in angle deviation is expanded further.

According to the foregoing configuration, the keyways 21 or 22 can beselected to satisfy torque characteristic requirements. The motor isthus used common to a variety of torque characteristic requirements witha reduction in cost.

The above-mentioned keyways 21, 22 are preferably different from oneanother in shape according to angle deviations. For example, FIG. 8Ashows a key 23 for fixing the permanent magnet type rotor unit 4. FIGS.8B to 8H show keys 24 for fixing the reluctance type rotor unit 6. Thekeys 24 of FIGS. 8B to 8H shall be selected depending on the angledeviation at the fixed position of the reluctance type rotor unit 6 inthe direction of rotation. Meanwhile, the keyways 21, 22 in the shafthole 20 of the reluctance type rotor unit 6 are formed into keywayshapes corresponding to respective angle deviations. This facilitatesassembly into a position of an angle deviation suited to desired torquecharacteristics without fault.

Among the shown examples, FIG. 8B is of a basic shape having arectangular cross section. FIGS. 8C, 8E, and 8G are ones chamfered ateither corner, and FIGS. 8D, 8F, and 8H at both corners, with theamounts of chamfer increased in succession. In this way, one of theplurality of keyways 21, 22 is formed into the basic shape shown in FIG.8B, and the rest of the keyways 21, 22 are formed into the shapes shownin FIGS. 8C to 8H, different at least in part from the basic shape. Thisallows commonality of keys 24 and requires partial machining alone toachieve the various shapes, thereby contributing a reduction in cost.

Next, a fourth embodiment will be described with reference to FIG. 9.

In the present embodiment, a gap dimension g₂ between the reluctancetype rotor unit 6 and the stator 3 is set smaller than a gap dimensiong₁ between the permanent magnet type rotor unit 4 and the stator 3.

According to the present embodiment, the permanent magnet type rotorunit 4 which undergoes higher centrifugal distortion due to theprovision of the permanent magnets 5 is given the greater gap dimensiong₁. Consequently, the permanent magnet type rotor unit 4 and thereluctance type rotor unit 6 are made equal in the limit of rotationspeed, thereby allowing higher rotation speed. Since the gap dimensiong₁ of the permanent magnet type rotor unit 4 has a small influence ontorque characteristics and the gap dimension g₂ of the reluctance typerotor unit 6 has a great influence on the torque characteristics, thereluctance type rotor unit 6 exercises a significant effect of improvingthe torque characteristics. The reluctance type rotor unit 6 improves inefficiency accordingly, with an improvement in motor efficiency.

Since the slits 8 formed in this reluctance type rotor unit 6 are givena slit width no less than twice the gap dimension g₁ between thepermanent magnet type rotor unit 4 and the stator 3, the slits 8 createsgaps greater than 2g₁, or the total length of the gaps lying on theoriginal magnetic paths of the permanent magnets 5, on the magneticpaths of leakage flux. Thus, the slits 8 surely exercise the effect ofpreventing flux leakage.

Next, a fifth embodiment will be described with reference to FIG. 10.

The present embodiment provides at least one bearing 25 for supportingthe rotor 2 rotatably. The bearing 25, or a bearing 25 of greatersupporting strength if a plurality of magnets are provided, is arrangedon the side of the permanent magnet type rotor unit 4. In the shownexample, a single bearing 25 is arranged on the side of the permanentmagnet type rotor unit 4. When bearings 25 are arranged on both sides,the one arranged on the side of the permanent magnet type rotor unit 4shall be greater in size and in supporting strength.

According to the present embodiment, the rotor 2 is stably supportedwith compact configuration because of the rational bearing arrangementthat the rotor 2 is supported by a bearing 25 of greater supportingstrength on the side of the permanent magnet type rotor unit 4 which ishigh in mass.

Next, a sixth embodiment will be described with reference to FIG. 11.

In the present embodiment, the permanent magnet type rotor unit 4 isarranged throughout the axial width of the stator 3. The reluctance typerotor unit 6 is placed outside the axial width of the stator 3. Suchconfiguration allows the q- and d-axis inductances to be changed at theend of the permanent magnet type rotor unit 4, with an increase inrotation speed.

Next, a seventh embodiment will be described with reference to FIG. 12.The foregoing first embodiment has dealt with the case where thepermanent magnet type rotor unit 4 has the plurality of permanentmagnets 5 arranged radially in a single layer. In the presentembodiment, outer permanent magnets 5 a and inner permanent magnets 5 bare arranged radially in double layers so that the permanent magnet typerotor unit 4 also forms magnetic paths between the permanent magnets 5 aand 5 b to obtain a reluctance torque. Even in the motor 1 having such apermanent magnet type rotor unit 4, the reluctance type rotor unit 6 maybe provided with slits 8 for the sake of the same effects.

Next, an eighth embodiment will be described with reference to FIG. 13.The foregoing third embodiment has dealt with the case where a pluralityof keyways 21 having different angle deviations are formed in thereluctance type rotor unit 6 having a plurality of salient pole portions7. In the present embodiment, as shown in FIG. 13, a plurality ofkeyways 21 having different angle deviations are formed in a rotor 26 ofa synchronous motor so that the keyways 21 can be selected to allow aphase selection/adjustment. Consequently, the synchronous motor alsooffers the same effects.

Next, a ninth embodiment will be described with reference to FIG. 14.The foregoing embodiments have dealt with the cases where the rotor 2 iscomposed of a permanent magnet type rotor unit 4 and a single reluctancetype rotor unit 6 which are directly connected in the axial direction,and the permanent magnet type rotor unit 4 and the reluctance type rotorunit 6 have an angle deviation therebetween. In the present embodiment,the rotor 2 is composed of the permanent magnet type rotor unit 4, afirst reluctance type rotor unit 6 a adjoining thereto, and a secondreluctance type rotor unit 6 b adjoining to the first reluctance typerotor unit 6 a. The first reluctance type rotor unit 6 a has slits 8 forpreventing flux leakage from the permanent magnets 5 but no angledeviation from the permanent magnet type rotor unit 4 in the directionof rotation. For desired torque characteristics, the first reluctancetype rotor unit 6 a and the second reluctance type rotor unit 6 b aregiven an appropriate angle deviation therebetween in the direction ofrotation.

According to the present embodiment, the absence of an angle deviationbetween the permanent magnet type rotor unit 4 and the first reluctancetype rotor unit 6 a surely prevents flux leakage from the permanentmagnets 5 at between the rotor units 4 and 6 a, thereby avoidingdeterioration in characteristics. Besides, the absence of a nonmagneticmaterial therebetween allows compact configuration and cost reductionwithout necessitating a drop in torque for the sake of flux leakageprevention. In addition, the provision of an arbitrary angle deviationbetween the first and second reluctance type rotor units makes itpossible to obtain desired torque characteristics such as higher torqueand lower vibration.

Incidentally, in the present embodiment, the second reluctance typerotor unit 6 b may be the rotor 26 of a synchronous motor as shown inthe eighth embodiment of FIG. 13. Such combination of reluctance typerotor units having different torque waveform characteristics furtherreduces torque ripples, thereby achieving lower vibration. While thepresent embodiment deals with the case of combining a single permanentmagnet type rotor unit 4 with two reluctance type rotor units 6 a and 6b, any numbers of rotor units may be combined with each other.

Next, a tenth embodiment will be described with reference to FIG. 15.The foregoing embodiments have dealt with the cases where the presentinvention is applied to an inner rotor type motor. The presentembodiment, as shown in FIG. 15, is an outer rotor type motor 31 whichhas a rotor 32 rotatably arranged around a stator 33. The rotor 32 iscomposed of a permanent magnet type rotor unit 34 having a plurality ofpermanent magnets 35 and a reluctance type rotor unit 36 having aplurality of salient pole portions 37. The rotor units 34 and 36 arecoupled with an angle deviation therebetween in the direction ofrotation. Slits 38 for preventing flux leakage from the permanentmagnets 35 are formed in the reluctance type rotor unit 36 with theangle deviation.

Even in such an outer rotor type motor 31, the application of thepresent invention offers the same operation and effects as in theforegoing embodiments.

The motors 1, 31 of the foregoing embodiments are compact in size, highin output, and high in efficiency, and thus are suitably applicable tothe compressor-driving motor shown in the second embodiment. Inaddition, the motors 1, 31 may be suitably applied to the driving motorsin hybrid, fuel-cell, and other types of electric vehicles, and thedriving motors of high-power fans.

In particular, hybrid type electric vehicles incorporating the foregoingmotors 1, 31 achieve higher outputs because of the reluctance torque ascompared to hybrid type electric vehicles using conventional magnet typemotors. Given the same motor output, when the motors are deactivated androtated by the engines during braking, downslope, and so on, theproduction of induced voltages is suppressed to lower iron loss sincethe rotor units contain smaller amounts of magnets. As a result, thehybrid type electric vehicles are increased in mileage per charge.Besides, even when the vehicles are running at high speed with themotors stopped, i.e., on the outputs of the engines alone, it ispossible to lower the voltage generated by the high speed rotations ofthe motors, thereby preventing degradation and breakage of the powersupply batteries and the like because the rotor units contain smalleramounts of magnets.

The same effects are also obtained from fuel-cell electric vehicles.

According to the motor of the present invention, flux leakage from theends of the permanent magnets of the permanent magnet type rotor unit tothe reluctance type rotor unit(s) is prevented to avoid deterioration incharacteristics resulting from flux leakage. Also, desired torquecharacteristics such as higher torque and lower vibration are achieved.

Although the present invention has been fully described in connectionwith the preferred embodiment thereof, it is to be noted that variouschanges and modifications apparent to those skilled in the art are to beunderstood as included within the scope of the present invention asdefined by the appended claims unless they depart therefrom.

1. A motor, comprising: a rotor including a permanent magnet type rotorunit having a plurality of permanent magnets and a reluctance type rotorunit having a plurality of salient pole portions, said rotor units beingcoupled to each other in an axial direction; and a stator that generatesa field for driving said rotor, said reluctance type rotor unit havingslits that prevent flux leakage from said plurality of permanentmagnets, each of said slits having a substantially smaller width than awidth of one of the plurality of permanent magnets and running withinprojected sections of the plurality of permanent magnets projected alongthe axial direction, along respective circumferential directionsthereof, said slits extending beyond said projected sections at bothends.
 2. The motor according to claim 1, further comprising anonmagnetic material arranged in said slits.
 3. The motor according toclaim 1, wherein said rotor is rotatably arranged around said stator andis cylindrical in shape.
 4. A hybrid type electric vehicle comprisingthe motor according to claim
 1. 5. A fuel-cell electric vehiclecomprising the motor according to claim
 1. 6. A motor, comprising: arotor that includes a permanent magnet type rotor unit having aplurality of permanent magnets and a reluctance type rotor unit having aplurality of salient pole portions, said rotor units being coupled toeach other in an axial direction; and a stator that generates a fieldfor driving said rotor, said reluctance type rotor unit having aplurality of slits, wherein the plurality of slits extend beyondprojected sections of the plurality of permanent magnets at both endsand wherein the width of each of the plurality of slits is smaller thana width of each of the projected sections of the plurality of permanentmagnets.
 7. The motor according to claim 6, further comprising anonmagnetic material arranged in the plurality of slits.
 8. The motoraccording to claim 6, wherein said rotor is rotatably arranged aroundsaid stator and is cylindrical in shape.
 9. A hybrid type electricvehicle comprising the motor according to claim
 6. 10. A fuel-cellelectric vehicle comprising the motor according to claim
 6. 11. Themotor according to claim 6, wherein the plurality of slits run along acenter of the projected sections of the plurality of permanent magnets.